Partitions with minimum range of sums

Description of the problem

Suppose we are given a finite list of real numbers \(a_1,\ldots,a_n\). We want to divide the index set \(\{1,\ldots,n\}\) into \(r\) non-empty pieces \[ \pi=\{p_1,\ldots,p_r\} \] so that the sums over the pieces are as close to each other as possible. For a block \(p\), put \[ S(p)=\sum_{i\in p}a_i . \] The discrepancy of the partition is \[ \nu(\pi)=\max_{p\in\pi}S(p)-\min_{p\in\pi}S(p). \] Thus, for fixed \(r\), the problem is to compute \[ \nu_{n,r}(a_1,\ldots,a_n)= \min_{\pi\in\Pi_{n,r}} \left( \max_{p\in\pi}\sum_{i\in p}a_i - \min_{p\in\pi}\sum_{i\in p}a_i \right), \] where \(\Pi_{n,r}\) is the set of partitions of \(\{1,\ldots,n\}\) into exactly \(r\) non-empty blocks.

The algorithm

I will write an exact algorithm. It is not meant to be a fast heuristic for large inputs. The problem is already hard for \(r=2\), so one should not expect a polynomial-time miracle.

function intervals(m, t):
    if |m| < t:
        return empty set

    if t = 1:
        return { [w(m), w(m)] with block m }

    first = least element of m
    result = empty set

    for each subset B of m containing first:
        R = m \ B

        if |R| >= t - 1:
            for each interval [L,U] in intervals(R, t - 1):
                s = w(B)
                add [min(s,L), max(s,U)] with block B to result

    return Pareto-minimal intervals in result

answer:
    choose [L,U] in intervals({1,...,n}, r) minimizing U - L

The algorithm is a dynamic programming procedure over subsets. A subset of the index set is represented by a bit mask \(m\), and \(w(m)\) denotes the sum of the entries whose indices occur in \(m\). For every pair \((m,t)\), the function intervals(m,t) stores the Pareto-minimal intervals \([L,U]\) that can occur when the subset \(m\) is partitioned into exactly \(t\) non-empty blocks, with all block sums lying between \(L\) and \(U\). The case \(t=1\) is immediate: the only possible block is the whole subset, hence the only interval is \([w(m),w(m)]\). For \(t>1\), the algorithm chooses the block containing the smallest element of \(m\), recursively partitions the complement into \(t-1\) blocks, and updates the resulting interval by adjoining the sum of the chosen block. Requiring the chosen block to contain the smallest available element removes the permutation symmetry among the blocks, so each unordered partition is generated once. After each step, dominated intervals are discarded: if \([L,U]\subseteq [L',U']\), then \([L',U']\) can never lead to a better range and is removed. The final answer is the interval of least width among intervals(fullMask,r).

An implementation

Let us start with base classes:

import scala.collection.mutable
import java.lang.Long.{bitCount, numberOfTrailingZeros}

case class Node(lo: Double, hi: Double, blocks: List[Long]) {
  def width: Double = hi - lo
}

case class Answer(value: Double, parts: Vector[Vector[Int]], sums: Vector[Double])

import scala.collection.mutable
import java.lang.Long.{bitCount, numberOfTrailingZeros}
class Node
class Answer

Now, the main solver:

def solve(x: IndexedSeq[Double], r: Int, eps: Double = 1e-10): Answer = {
  require(1 <= r && r <= x.length)
  require(x.length <= 62)

  val n    = x.length
  val sums = mutable.HashMap[Long, Double](0L -> 0.0)
  val memo = mutable.HashMap.empty[(Long, Int), Vector[Node]]

  def sum(m: Long): Double =
    sums.getOrElseUpdate(
      m,
      sum(m & (m - 1L)) + x(numberOfTrailingZeros(m))
    )

  def subsets(m: Long): Iterator[Long] =
    Iterator.iterate(m)(s => (s - 1L) & m).takeWhile(_ != 0L) ++ Iterator.single(0L)

  def dominates(a: Node, b: Node): Boolean =
    a.lo >= b.lo - eps &&
    a.hi <= b.hi + eps &&
    (a.lo > b.lo + eps || a.hi < b.hi - eps)

  def pareto(v: Vector[Node]): Vector[Node] =
    v.filter(b => !v.exists(a => dominates(a, b)))

  def intervals(m: Long, t: Int): Vector[Node] =
    memo.getOrElseUpdate(
      (m, t),
      {
        if (bitCount(m) < t) Vector.empty
        else if (t == 1) {
          val s = sum(m)
          Vector(Node(s, s, m :: Nil))
        }
        else {
          val first = m & -m

          pareto(
            subsets(m ^ first).flatMap { sub =>
              val block = sub | first
              val rem   = m ^ block

              if (bitCount(rem) < t - 1) Iterator.empty
              else {
                val s = sum(block)
                intervals(rem, t - 1).iterator.map { z =>
                  Node(math.min(s, z.lo), math.max(s, z.hi), block :: z.blocks)
                }
              }
            }.toVector
          )
        }
      }
    )

  val best = intervals((1L << n) - 1L, r).minBy(_.width)

  Answer(
    value = best.width,
    parts = best.blocks
      .map(m => (0 until n).filter(i => ((m >>> i) & 1L) == 1L).toVector)
      .toVector,
    sums = best.blocks.map(sum).toVector
  )
}

def solve(x: IndexedSeq[Double], r: Int, eps: Double): Answer

The only slightly non-obvious line is the Pareto reduction. Suppose one construction gives the interval \([L,U]\), and another gives \([L',U']\). If \[ L\geq L' \quad\text{and}\quad U\leq U', \] then \([L,U]\subseteq [L',U']\). The larger interval cannot be better for minimizing \(U-L\). So the larger interval may be discarded.

Let us test the function on a small example.

val a = solve(Vector(1.0, 0.45, 0.40, 0.40, 0.10, 0.10), 4)

a.value

val a: Answer = Answer(0.55,Vector(Vector(0), Vector(1), Vector(2, 5), Vector(3, 4)),Vector(1.0, 0.45, 0.5, 0.5))
val res0: Double = 0.55

The value is the minimum possible discrepancy among all partitions into \(4\) blocks. The returned partition is encoded by zero-based indices.

a.parts.zip(a.sums).zipWithIndex.foreach {
  case ((p, s), j) => println(s"p$j = $p ; sum = $s")
}

p0 = Vector(0) ; sum = 1.0
p1 = Vector(1) ; sum = 0.45
p2 = Vector(2, 5) ; sum = 0.5
p3 = Vector(3, 4) ; sum = 0.5

Here is a reproducible random example.

val rng = new scala.util.Random(2026L)
val x = Vector.fill(12)(rng.nextDouble())
val b = solve(x, 3)

val rng: scala.util.Random = scala.util.Random@6f430ea8

val x: scala.collection.immutable.Vector[Double] = Vector(0.6186327814734252, 0.849209341093155, 0.7903839677394705, 0.5296053232288097, 0.8416668624371814, 
0.14829601053373576, 0.8437822755735771, 0.5847572137985457, 0.1667271317594733, 0.7157842860912638, 0.5392902493576879, 0.27949326840295363)

val b: Answer = Answer(0.007453088971694388,Vector(Vector(0, 4, 6), Vector(1, 5, 7, 9), Vector(2, 3, 8, 10, 11)),Vector(2.304081919484184, 2.2980468515167005, 2.305499940488395))

b.value

val res2: Double = 0.007453088971694388

The three block sums are:

b.sums

val res3: Vector[Double] = Vector(2.304081919484184, 2.2980468515167005, 2.305499940488395)

Their range is:

b.sums.max - b.sums.min

val res4: Double = 0.007453088971694388

which agrees with the value returned by solve.

The complexity is exponential. The memoized state is a pair \((m,t)\), where \(m\) is a subset mask and \(t\) is the number of blocks still required. There are at most \(r2^n\) such states, and each state may enumerate many submasks. Thus the algorithm is exact, but it is suitable only for moderately sized inputs.

The important point is that this function is not the greedy equal-pile procedure. The greedy procedure gives a fast balancing heuristic. The present function computes the actual optimum

\[ \min_{\pi\in\Pi_{n,r}} \left( \max_{p\in\pi}\sum_{i\in p}a_i - \min_{p\in\pi}\sum_{i\in p}a_i \right). \]